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Place Versus Response Learning in Fish: a Comparison Between Species

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Place Versus Response Learning in Fish: a Comparison Between Species Place versus response learning in fish: a comparison between species. McAroe, C. L., Craig, C. M., & Holland, R. A. (2015). Place versus response learning in fish: a comparison between species. Animal Cognition, 1-9. https://doi.org/10.1007/s10071-015-0922-9 Published in: Animal Cognition Document Version: Peer reviewed version Queen's University Belfast - Research Portal: Link to publication record in Queen's University Belfast Research Portal Publisher rights http://link.springer.com/article/10.1007%2Fs10071-015-0922-9 General rights Copyright for the publications made accessible via the Queen's University Belfast Research Portal is retained by the author(s) and / or other copyright owners and it is a condition of accessing these publications that users recognise and abide by the legal requirements associated with these rights. Take down policy The Research Portal is Queen's institutional repository that provides access to Queen's research output. Every effort has been made to ensure that content in the Research Portal does not infringe any person's rights, or applicable UK laws. If you discover content in the Research Portal that you believe breaches copyright or violates any law, please contact [email protected]. Download date:28. Sep. 2021 1 Place versus Response Learning in Fish: A Comparison between 2 Species 3 Claire L. McAroe1,2 [email protected], +44 (0) 2892664256 4 Cathy M Craig2 and Richard A Holland1 5 1School of Biological Sciences, Queen’s University Belfast, Medical Biology 6 Centre, 97 Lisburn Road, Belfast, BT9 7 BL, Northern Ireland 7 2School of Psychology, Queen’s University Belfast, University Road, Belfast, 8 BT7 1NN, Northern Ireland 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 26 Abstract 27 Place learning is thought to be an adaptive and flexible facet of navigation. 28 Due to the flexibility of this learning, it is thought to be more complex than the 29 simpler strategies such as learning a particular route or navigating through the 30 use of cues. Place learning is crucial in a familiar environment as it allows an 31 individual to successfully navigate to the same endpoint, regardless of where 32 in the environment the journey begins. Much of the research to date focusing 33 on different strategies employed for navigation has used human subjects or 34 other mammals such as rodents. In this series of experiments, the spatial 35 memory of four different species of fish (goldfish, killifish, zebrafish and 36 Siamese fighting fish) was analysed using a plus maze set-up. Results 37 suggest that three of the species showed a significant preference for the 38 adoption of a place strategy during this task whereas zebrafish showed no 39 significant preference. Furthermore, zebrafish took significantly longer to learn 40 the task than the other species. Finally, results suggest that zebrafish took the 41 least amount of time (seconds) to complete trials both during training and 42 probe. 43 Keywords: Spatial memory, Spatial cognition, Fish, Animal model, Navigation 44 Introduction 45 In the animal kingdom, spatial memory is important for many reasons 46 including avoiding predation, prey detection and finding a mate (Wolbers & 47 Hegarty 2010; White & Brown 2014). There are two categories associated 48 with spatial memory and navigation (van Gerven et al. 2012). The first are 49 called “egocentric processes” and involve encoding features of the 50 environment in relation to where the individual is currently located (Shelton & 2 51 McNamara 2001). These processes involve learning to navigate to a location 52 using landmarks in the environment as beacons or by learning a series of 53 turning responses (O’Keefe & Nadel 1978; van Gerven et al. 2012). 54 Egocentric navigation is relatively simple and therefore allows spatial 55 memories to be formed easily (van Gerven et al. 2012). Such methods do, 56 however, lack flexibility, particularly in response to changes within the 57 environment, meaning the individual will be less likely to reach their desired 58 location from a novel start point (Rodriguez et al. 1994). 59 O’Keefe and Nadel argued that animals are also able to navigate using 60 another set of processes which, although more cognitively demanding, are 61 able to adapt more readily to changes within the environment (O’Keefe & 62 Nadel 1978; Rodriguez et al. 1994). These are called “allocentric processes”. 63 Cognitive mapping, first proposed by Tolman, is the best known example of 64 an allocentric process and is described as a complex mental representation of 65 a familiar environment that can be used to influence spatial behaviour and 66 decision-making (Tolman 1948; O’Keefe & Nadel 1978). One of the key 67 features of such an allocentric process is that an individual is able to navigate 68 based on the spatial relationships between multiple landmarks, sensory 69 features and possible routes within a particular environment (Iaria et al. 2009). 70 As the individual moves though the environment, its cognitive map is 71 continuously updated, making for more robust spatial memory that is also 72 more relevant and current (Cheeseman et al. 2014). This means that changes 73 within the environment, such as removal of specific landmarks or attempting 74 to reach the same goal location from a novel start point, will not significantly 75 affect the individual’s spatial memory (Wolbers & Hegarty 2010). 3 76 Many experiments have been conducted using maze tests to analyse 77 spatial memory in a variety of species, with mammals and birds being the 78 most popular animals to study (Tolman et al. 1946; O'Keefe & Nadel 1979; 79 Clayton & Krebs 1995; Shettleworth & Westwood 2002; Hamilton et al. 2009). 80 Both taxa possess a hippocampal structure in the brain which is thought to be 81 a key area associated with complex spatial memory abilities (see: Pravosudov 82 & Roth II 2013). Some studies have also shown that individuals who navigate 83 through complex environments on a regular basis, or perform complex spatial 84 memory tasks, are likely to have an enlarged hippocampus (Clayton & Krebs 85 1995; Maguire et al. 2000). However, the lack of a hippocampal structure in 86 other animal classes does not necessarily mean that such species are 87 incapable of flexible navigation. 88 Fish are the most numerous of all vertebrate species (Casebolt et al. 89 1998) and many live in complex environments, some of which are subject to 90 instability and therefore require the animals to have powerful spatial memory 91 capabilities (Brown 2014). Rodriguez and colleagues showed that, like 92 mammals and birds, goldfish are capable of navigating using both egocentric 93 and allocentric processes during maze tests (Rodriguez et al. 1994). The 94 same authors have also been able to manipulate navigational strategy by 95 ablating brain regions of fish, directly suggesting that there are specific areas 96 of the fish brain responsible for different navigational processes (Salas et al. 97 1996; López et al. 2000; Broglio et al. 2010). Despite these suggestions, a 98 recent search on Web of Knowledge (January 2015) using “spatial memory” 99 as the search criterion reported 54,109 articles with only 216 citing fish as the 100 study species. Furthermore, many of these articles focus on the large-scale 4 101 navigation abilities (i.e. migration) of particular species rather than on which 102 strategies fish use to solve spatial tasks (Dittman & Quinn 1996; Saito & 103 Watanabe 2005) . Finally, there have been limited studies comparing the 104 similarities and differences in spatial memory across species of fish with many 105 experiments focusing on only one study species (e.g. Braithwaite & De Perera 106 2006; Shapiro & Jensen 2009; Lamb et al. 2012). Such research would 107 highlight that complex spatial memory is an attribute of fish as a taxonomic 108 group rather than just of specific species. 109 This study used four different species of fish to assess the length of 110 time each took to learn a spatial task. It also analysed which strategy each 111 species preferred (egocentric or allocentric) for spatial memory. The four 112 species were goldfish, Siamese fighting fish, zebrafish and a type of killifish. 113 Each of these species is teleost (from the class Actinopterygii) with three from 114 the order Cypriniformes and Siamese fighting fish from the order Perciformes 115 (www.fishbase.org). It is important that they are all from the same class, as 116 the teleost brain is thought to be very similar across fish species, and is 117 comparable on some levels to the mammalian brain (Tropepe & Sive 2003). 118 As mentioned previously, the hippocampus is thought to be crucial for 119 allocentric spatial memory performance in mammals, the area associated with 120 similar spatial memory abilities in teleost fish has been identified as the lateral 121 pallium area of the telencephalon, and impairment to this area results in a 122 marked reduction in allocentric spatial learning in these animals (see: Broglio 123 et al. 2003 for a review). 124 All but one of these species (killifish) are thought of as domesticated 125 fish (Gordon & Axelrod 1968; Andrews 2002; Spence et al. 2011) and popular 5 126 laboratory species in the studies of a variety of both physiological and 127 cognitive experiments (Roitblat et al. 1982; Kishi 2004; Portavella & Vargas 128 2005). The final species was chosen as it is gaining popularity within similar 129 fields (Herrera & Jagadeeswaran 2004). Goldfish are the most domesticated 130 of all, and therefore there is limited available information about their natural 131 habitat. However as descendants of carp, it is assumed they tend to occupy 132 ponds and other such bodies of water (Andrews 2002).
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